Ligand-specific regulation of the endogenous mu-opioid receptor by chronic treatment with mu-opioid peptide agonists.

Since the discovery of the endomorphins (EM), the postulated endogenous peptide agonists of the mu-opioid receptors, several analogues have been synthesized to improve their binding and pharmacological profiles. We have shown previously that a new analogue, cis-1S,2R-aminocyclohexanecarboxylic acid(2)-endomorphin-2 (ACHC-EM2), had elevated mu-receptor affinity, selectivity, and proteolytic stability over the parent compound. In the present work, we have studied its antinociceptive effects and receptor regulatory processes. ACHC-EM2 displayed a somewhat higher (60%) acute antinociceptive response than the parent peptide, EM2 (45%), which peaked at 10 min after intracerebroventricular (icv) administration in the rat tail-flick test. Analgesic tolerance developed to the antinociceptive effect of ACHC-EM2 upon its repeated icv injection that was complete by a 10-day treatment. This was accompanied by attenuated coupling of mu-sites to G-proteins in subcellular fractions of rat brain. Also, the density of mu-receptors was upregulated by about 40% in the light membrane fraction, with no detectable changes in surface binding. Distinct receptor regulatory processes were noted in subcellular fractions of rat brains made tolerant by the prototypic full mu-agonist peptide, DAMGO, and its chloromethyl ketone derivative, DAMCK. These results are discussed in light of the recently discovered phenomenon, that is, the "so-called biased agonism" or "functional selectivity".

Lack of regulatory changes of µ-opioid receptors by 14-methoxymetopon treatment in rat brain. Further evidence for functional selectivity.

Here we have studied regulatory changes of µ-opioid receptors accompanying in vivo 14-methoxymetopon treatments of rats. Previously, this ligand has been shown to be an extremely potent, centrally acting µ-opioid specific analgesic with low physical dependence, tolerance, respiratory depression, constipation and other side effects. Our work shows that it is a highly potent full agonist of µ-opioid receptor coupled G-protein signaling in vitro, alike the well-known opioid agonist, etorphine. However, unlike etorphine, which desensitized and down-regulated the endogenous µ-opioid receptors, 14-methoxymetopon, given to rats intraperitoneally (i.p.) either acutely or chronically, did not change the binding or G-protein signaling of µ-opioid receptors in rat brain subcellular membranes. Thereby, these data provide further evidence that there is no direct relationship between the efficacy of the ligand in signaling and its ability to internalize or desensitize the receptor. Viewed collectively with published work, it is discussed that µ-opioid receptors display functional selectivity, also called 'biased agonism'. This concept implies that each ligand may induce unique, ligand-specific receptor conformation that can result in distinct agonist- directed trafficking and/or signal transduction pathways associated with the receptor. Ligand-specific signaling may open up new directions for designing potent analgesics that do not interact with unwanted signaling pathways, which mediate undesired side-effects, such as tolerance and dependence.

A comprehensive study on the putative δ-opioid receptor (sub)types using the highly selective δ-antagonist, Tyr-Tic-(2S,3R)-ß-MePhe-Phe-OH.

The goal of our work was a throughout characterization of the pharmacology of the TIPP-analog, Tyr-Tic-(2S,3R)-ß-MePhe-Phe-OH and see if putative δ-opioid receptor subtypes can be distinguished. Analgesic latencies were assessed in mouse tail-flick assays after intrathecal administration. In vitro receptor autoradiography, binding and ligand-stimulated [(35)S]GTPγS functional assays were performed in the presence of putative δ(1)-(DPDPE: agonist, BNTX: antagonist), δ(2)-(agonist: deltorphin II, Ile(5,6)-deltorphin II, antagonist: naltriben) and µ-(DAMGO: agonist) opioid ligands. The examined antagonist inhibited the effect of DPDPE by 60%, but did not antagonize δ(2)- and µ-agonist induced analgesia. The radiolabeled form identified binding sites with K(D)=0.18 nM and receptor densities of 102.7 fmol/mg protein in mouse brain membranes. The binding site distribution of the [(3)H]Tyr-Tic-(2S,3R)-ß-MePhe-Phe-OH agreed well with that of [(3)H]Ile(5,6)-deltorphin II as revealed by receptor autoradiography. Tyr-Tic-(2S,3R)-ß-MePhe-Phe-OH displayed 2.49±0.06 and 0.30±0.01 nM potency against DPDPE and deltorphin II in the [(35)S]GTPγS functional assay, respectively. The rank order of potency of putative δ(1)- and δ(2)-antagonists against DPDPE and deltorphin was similar in brain and CHO cells expressing human δ-opioid receptors. Deletion of the DOR-1 gene resulted in no residual binding of the radioligand and no significant DPDPE effect on G-protein activation. Tyr-Tic-(2S,3R)-ß-MePhe-Phe-OH is a highly potent and δ-opioid specific antagonist both in vivo and in vitro. However, the putative δ(1)- and δ(2)-opioid receptors could not be unequivocally distinguished in vitro.

Long-lasting, distinct changes in central opioid receptor and urinary bladder functions in models of schizophrenia in rats.

Ketamine treatments and social isolation of rats reflect certain features of schizophrenia, among them altered pain sensitivity. To study the underlying mechanisms of these phenomena, rats were either housed individually or grouped for 33 days after weaning, and treated with either ketamine or saline for 14 days. After one month re-socialization, the urinary bladder capacity by ultrasound examination in the anesthetized animals, and changes of µ-opioid receptors by saturation binding experiments using a specific µ-opioid agonist [(3)H]DAMGO were determined. G-protein signaling was investigated in DAMGO-stimulated [(35)S]GTPγS functional assays. Ketamine treatment significantly decreased the bladder volume and isolation decreased the receptor density in cortical membranes. Among all groups, the only change in binding affinity was an increase induced by social isolation in the cortex. G-protein signaling was significantly decreased by either ketamine or social isolation in this tissue. Ketamine treatment, but not housing, significantly increased µ-opioid receptor densities in hippocampal membranes. Both ketamine and isolation increased the efficacy, while the potency of signaling was decreased by any treatment. Ketamine increased the receptor density and G-protein activation; while isolation decreased the efficacy of G-protein signaling in hippocampal membranes. The changes in the co-treated group were similar to those of the isolated animals in most tests. The distinct changes of opioid receptor functioning in different areas of the CNS may, at least partially, explain the augmented nociceptive threshold and morphine potency observed in these animals. Changes in the relative urinary bladder suggest a detrusor hyperreflexia, another sign of schizophrenia.

Pharmacology of a new tritiated endomorphin-2 analog containing the proline mimetic cis-2-aminocyclohexanecarboxylic acid.

As part of ongoing work aimed at generating proteolytically stable, readily applicable, radiolabeled endomorphin-2 (EM-2) analogs for elucidation of the topological requirements of peptide binding to µ-opioid receptors, we report here on the synthesis, radiolabeling, binding kinetics and binding site distribution of an EM-2 analog in which Pro(2) is replaced by 2-aminocyclohexanecarboxylic acid, ACHC. [(3)H][(1S,2R)ACHC](2)EM-2 (specific activity 63.49Ci × mmol(-1)) bound specifically to its binding sites with high affinity (K(D) = 0.55 ± 0.06 nM) and saturably, yielding a receptor density, B(max) of 151 ± 4 fmol × mg protein(-1) in rat brain membranes. A similar affinity value was obtained in kinetic assays. Both Na(+) and Gpp(NH)p decreased the affinity, proving the agonist character of the radioligand. Specific µ-opioid ligands displaced the radioligand with much higher affinities than did δ- and κ-ligands. The autoradiographic distribution of the binding sites of [(3)H][(1S,2R)ACHC](2)EM-2 agreed well with the known locations of the µ-opioid receptors in the rat brain. In consequence of its high affinity, selectivity and enzymatic resistance [19], the new radioligand will be a good tool in studies of the topographical requirements of µ-opioid-specific peptide binding.

Synthesis and pharmacological characterization of a novel, highly potent, peptidomimetic delta-opioid radioantagonist, [3H]Tyr-Tic-(2S,3R)-beta-MePhe-Phe-OH.

[(3)H]Tyr-Tic-(2S,3R)-beta-MePhe-Phe-OH (where Tic: 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid) with a specific radioactivity of 53.7 Ci/mmol was synthesized and characterized in receptor binding assays at 25 degrees C in rat brain membranes. The specific binding was saturable and displayed high affinity, with a K(D) of 0.16+/-0.005 nM and B(max) of 85.9+/-6.3 fmol/mg protein. NaCl increased its affinity by about 4-fold in membranes of rat brain and Chinese Hamster Ovary Cells stably transfected with the human delta-opioid receptors (hDOR-CHO) showing that the new ligand is an antagonist. The prototypic delta-opioid ligands were much more potent than mu- or kappa-specific ligands in competition assays. The autoradiographic distribution of the binding sites of the new ligand agreed with the known locations of the delta-opioid receptors in rat brain. The unlabeled new ligand was about 7-fold more potent than the parent peptide in competing for the binding sites of [(3)H]Tyr-Tic-(2S,3R)-beta-MePhe-Phe-OH in rat brain membranes. Likewise, the threo-beta-methyl analog was 3.8-fold more potent than the parent compound in antagonizing the effect of DPDPE in the [(35)S]GTPgammaS functional assay in hDOR-CHO membranes. The new, highly potent, conformationally constrained antagonist may be a valuable pharmacological tool in understanding the structural and topographical requirements of peptide ligand binding to the delta-opioid receptors.